Vermont composite geocoding service built with VT E911 data. This service can be used by ArcGIS Pro 2.8.x+ to batch geocode addresses stored in a table. It also can be used as a geocoder with most ArcGIS Online apps, as well as QGIS. [How To Use The Vermont Geocoding Service]This ArcGIS Online item utilizes the ArcGIS Server geocoding service at this REST Endpoint: https://maps.vcgi.vermont.gov/arcgis/rest/services/EGC_services/GCS_E911_COMPOSITE_SP_v2/GeocodeServer

The ArcGIS World Geocoding Service finds addresses and places in all supported countries around the world in a single geocoding service. The service can find point locations of addresses, cities, landmarks, business names, and other places. The output points can be visualized on a map, inserted as stops for a route, or loaded as input for a spatial analysis.The service is available as both a geosearch and geocoding service:Geosearch Services – The primary purpose of geosearch services is to locate a feature or point of interest and then have the map zoom to that location. The result might be displayed on the map, but the result is not stored in any way for later use. Requests of this type do not require a subscription or a credit fee. Geocoding Services – The primary purpose of geocoding services is to convert an address to an x,y coordinate and append the result to an existing record in a database. Mapping is not always involved, but placing the results on a map may be part of a workflow. Batch geocoding falls into this category. Geocoding requires a subscription. An ArcGIS Online Subscription, or ArcGIS Location Platform Subscription, will provide you access to the ArcGIS World Geocoding service for batch geocoding.The service can be used to find address and places for many countries around the world. For detailed information on this service, including a data coverage map, visit the ArcGIS World Geocoding service documentation.

DASC provides a free, statewide geocoding service that uses NG911 address points and road centerline data as a base. For directions on using the geocoding service, see this guide.

If you do not see the Web Service you are looking for, or still having trouble connecting to your service, please contact us at dasc@ku.edu.

The full Kansas geospatial catalog is administered by the Kansas Data Access & Support Center (DASC) and can be found at the following URL: https://hub.kansasgis.org/

The Street_and_Address_Composite will return a geographic coordinate when a street address is entered. A user can enter an address either manually or by bulk input from a database or other source.The geocoder returns a coordinate pair and standardized address for each input address it is able to match. The NYS ITS Geospatial Services geocoder uses a series of combinations of reference data and configuration parameters to optimize both the likelihood of a match and the quality of the results. The reference data supporting the geocoder is stored in Federal Geographic Data Committee (FGDC) standard.The first composite locator (Street_and_Address_Composite) is made up of the following set of locators which are most likely to return a high quality hit. The locators are listed in the order in which they will be accessed along with a brief description of the locator's source data. These six locators will generate the majority of the results when geocoding addresses.Locator NameSource DataDescription1A_SAM_AP_ZipNameSAM Address PointsSAM address points using the postal zip code name for the city name in the locator.1B_SAM_AP_CTNameSAM Address PointsSAM address points. The city or town name is used for the city name in the locator.1C_SAM_AP_PlaceNameSAM Address PointsSAM address points. The city name is populated using the NYS Villages and Indian Reservations, the Census Designated Places and Alternate Acceptable Zip Code Names from the USPS. These names do not exist everywhere so there will be a limited number of points in this locator.3A_SS_ZipNameNYS Street SegmentsNYS Street Segments dataset using the postal zip code name for the city name in the locator. The location is interpolated from an address range on the street segment. The city name can be different for the left and right sides of the streets.3B_SS_CTNameNYS Street SegmentsNYS Street Segments using the city or town name for the city name in the locator. The location is interpolated from an address range on the street segment.3C_SS_PlaceNameNYS Street SegmentsNYS Street Segments using an alternate place name for the city field. This field is populated using the NYS Villages and Indian Reservations, the Census Designated Places and Alternate Acceptable Zip Code Names from the USPS. These areas do not exist everywhere so there will be a limited number of segments with this attribute. The location is interpolated from an address range on the street segment.For more information about the geocoding service, please visit: https://gis.ny.gov/address-geocoder.For documentation on how to add these locators to ArcGIS, please reference Adding the Statewide Geocoding Web Service. If you would like these locators to be your default locators in ArcGIS, copy DefaultLocators.xml to C:\Users<username>\AppData\Roaming\ESRI\Desktop10.X\Locators, where

This geocoding service provides the ability to perform tabular geocoding, reverse geocoding, and identifying results for locations that contain sub-addresses. This service and the supporting data are provided by the AddressNC program.A geocoding locator file is also available for users of ArcGIS Pro or ArcGIS Desktop in an offline/disconnected environment.

OpenSearch service for the geocoding of addresses and geonames in Germany for internal application in federal authorities. The service is based on the database of the Georeferenced Address Data — Bund (GA). The Federal Office for Cartography and Geodesy (BKG) prepares the data and operates the web service developed at the service centre of the BKG.

This Africa Geocoding locator is a view of the World Geocoding Service constrained to search for places in the countries of Africa. The World Geocoding Service finds addresses and places in all supported countries around the world in a single geocoding service. The service can find point locations of addresses, cities, landmarks, business names, and other places. The output points can be visualized on a map, inserted as stops for a route, or loaded as input for a spatial analysis.The service is available as both a geosearch and geocoding service:Geosearch Services – The primary purpose of geosearch services is to locate a feature or point of interest and then have the map zoom to that location. The result might be displayed on the map, but the result is not stored in any way for later use. Requests of this type do not require a subscription or a credit fee. Geocoding Services – The primary purpose of geocoding services is to convert an address to an x,y coordinate and append the result to an existing record in a database. Mapping is not always involved, but placing the results on a map may be part of a workflow. Batch geocoding falls into this category. Geocoding requires a subscription. An ArcGIS Online subscription will provide you access to the World Geocoding service for batch geocoding.The service can be used to find address and places for many countries around the world. For detailed information on this service, including a data coverage map, visit the World Geocoding service documentation.

VT E911 Composite geocoder - uses ESITE, RDSNAME, and RDSRANGE. REFRESHED WEEKLY. VCGI, in collaboration with the VT E911 Board, has created a suite of geocoding services that can be used to batch geocode addresses using ArcGIS Desktop 10.x. This service can also be integrated into ESRI ArcGIS web-based mapping applications.Input Address Requirements Must use valid E911 addresses (street style addressing...no P.O. box addresses!) and E911 town names. Limitations Don't attempt to geocode more than 50000 records or so. You must have an Internet connection to use the services. A DSL, cable, or other high bandwidth connection is the best option. Addresses other than E911 addresses are not supported. ArcGIS Pro - How To:Startup ArcGIS ProUnder the "Insert" ribbon select Connections --> New ArcGIS Server. Server URL = https://maps.vcgi.vermont.gov/arcgis/servicesBrowse to the ./EGC_services folder and select GEOCODE_COMPOSITE (or GEOCODE_ESITE).Add the table you want to geocode to project, then right-click and select "Geocode Table". Choose the “Go to Tool” option at the bottom of the dialogue box.Make selections and run geocoder.ArcGIS Desktop (ArcMap) - How To: Startup ArcMap 10+ Add a table containing VT addresses to geocode. ?Click the "Add Data" button.Navigate to your table, choose to add your tableRight-click on the table in the table of contentsSelect "Geocode Addresses...".Select "Add" in the dialog box.Browse to the "GIS Servers" icon in your catalog, then double click "Add ArcGIS Server".Select "Use GIS Services", then Next.ServerURL = https://maps.vcgi.vermont.gov/arcgis/services then click finish.Browse to "arcgis on maps.vcgi.org (user)". Browse to .\EGC_services folder.Select GECODE_ESITE (or GEOCODE_COMPOSITE). Click OK.Select whatever options you want in the geocode dialog box, including output, then click ok.The output will be automatically added to your ArcMap session.

The BC Address Geocoder is a REST API that can used to resolve the physical locations of addresses and place names in British Columbia (i.e., their latitude and longitude). It also provides additional capability, such as correcting and standardizing civic and non-civic addresses, reverse geocoding addresses within areas of interest, locating intersections and identifying parcels associated with specific addresses. For more information please see the glossary and the developer guide. The API is governed by these terms of use, with the exception of the parcels API resource (see note below). Note: the parcels API resource is restricted to B.C. government ministries use only. Ministries should contact DataBC to request an API key.

Geocode addresses for the Portland metropolitan region. This locator is an ArcGIS Pro version of the RLIS Address Locator, with autosuggestion capabilities enabled. It is based on RLIS data including the Master Address File and Streets and supports finding an address in a single-line format. It is available both as a geocode service and as a downloadable locator package. This is the ArcGIS Pro version of the downloadable locator package, the ArcMap-compatible version is available under the name "RLIS Address Locator - Download." The new ArcGIS Pro version of the geocode service with autosuggest functionality enabled is available under the name "RLIS Address Locator (Pro)." Date of last data update: 2025-07-28 This is official RLIS data. Contact Person: Alicia Wood alicia.wood@oregonmetro.gov 503-813-7561 RLIS Metadata Viewer: https://gis.oregonmetro.gov/rlis-metadata/#/details/3736 RLIS Terms of Use: https://rlisdiscovery.oregonmetro.gov/pages/terms-of-use

The VGIN Composite Geocoding service is a cascading locator consisting of Virginia Address Points, Virginia RCL (Road Centerlines), Virginia Community Anchor Institutions (CAI), and several other data layers that supply the end user with returned XY coordinates based on input address number or address name.

The MAR is a SOAP web service with multiple geocoding and address verification operations. This page includes information and examples for using the MAR to look up information about locations within DC through a code based querying interfaces.

Geocode addresses for the Portland metropolitan region. The locator is based on RLIS data including the Master Address File and streets and supports finding an address in a single-line format. It is available both as a geocode service and as a downloadable locator package. This is the original ArcMap-compatible downloadable locator package, the original geocode service is available under the name "RLIS Address Locator." The new ArcGIS Pro version of the downloadable locator package with autosuggest functionality enabled is available under the name "RLIS Address Locator (Pro) - Download." Date of last data update: 2025-07-28 This is official RLIS data. Contact Person: Alicia Wood alicia.wood@oregonmetro.gov 503-813-7561 RLIS Metadata Viewer: https://gis.oregonmetro.gov/rlis-metadata/#/details/2751 RLIS Terms of Use: https://rlisdiscovery.oregonmetro.gov/pages/terms-of-use

Address Geocoding Software Market Outlook

According to our latest research, the global Address Geocoding Software market size was valued at USD 1.87 billion in 2024, and it is anticipated to grow at a robust CAGR of 12.1% from 2025 to 2033. By the end of 2033, the market is projected to reach USD 5.23 billion. This significant growth is driven by the increasing demand for precise location-based services across various sectors and the rapid adoption of advanced geospatial analytics solutions. The expanding use of geocoding technology in logistics, retail, and emergency response, as well as the proliferation of cloud-based deployment models, are key factors powering the market’s upward trajectory as per our latest research.

The primary growth driver for the Address Geocoding Software market is the escalating need for accurate and real-time geospatial data in business operations. Organizations across industries such as retail, logistics, and banking are leveraging geocoding software to enhance operational efficiency, optimize delivery routes, and improve customer experiences. With the surge in e-commerce and the growing importance of location intelligence in marketing, there is a marked increase in the adoption of geocoding solutions. Additionally, the integration of geocoding software with advanced technologies such as artificial intelligence and machine learning is enabling businesses to derive actionable insights from complex datasets, further fueling market growth.

Another significant factor contributing to the market’s expansion is the shift towards cloud-based deployment models. Cloud-based address geocoding solutions offer scalability, flexibility, and cost-effectiveness, making them attractive to both large enterprises and small and medium-sized businesses. The ability to access geocoding services remotely and integrate them seamlessly with other cloud-based applications is driving widespread adoption. Cloud deployment also supports real-time data processing and analytics, which is crucial for applications such as emergency response, fleet management, and dynamic mapping. As organizations increasingly prioritize digital transformation, the demand for cloud-enabled geocoding solutions is expected to rise substantially.

Moreover, the Address Geocoding Software market is benefiting from growing investments in smart city initiatives and urban planning projects worldwide. Governments and municipal authorities are deploying geocoding software to support infrastructure development, optimize public transportation, and enhance emergency response capabilities. The integration of geospatial analytics into urban planning is enabling more efficient resource allocation and improved citizen services. Additionally, the proliferation of Internet of Things (IoT) devices and the increasing use of connected vehicles are generating vast amounts of location data, which further boosts the need for sophisticated geocoding solutions.

From a regional perspective, North America currently holds the largest share of the Address Geocoding Software market, followed closely by Europe and the Asia Pacific. North America’s dominance is attributed to the high concentration of technology-driven enterprises, strong adoption of location-based services, and significant investments in geospatial analytics. The Asia Pacific region is witnessing the fastest growth, driven by rapid urbanization, expanding e-commerce sectors, and increasing government initiatives to develop smart infrastructure. Meanwhile, Europe continues to demonstrate steady growth, supported by stringent data privacy regulations and the widespread use of advanced mapping technologies in transportation and logistics. The Middle East & Africa and Latin America are also emerging as promising markets, fueled by infrastructural development and the growing adoption of digital technologies.

Component Analysis

The Address Geocoding Software market is segmented by component into Software and Services, each playing a pivotal role in shaping the market’s landscape. The software segment is driven by the increasing demand for standalone geocoding applications and integrated solutions that can be embedded into existing enterprise systems. These software solutions are designed to convert address data into geographic coordinates, enabling organizations to leverage accurate location information for a wide range of applications, from logistics optimization to t

Geocoding API Market Outlook

According to our latest research, the global Geocoding API market size reached USD 1.45 billion in 2024, reflecting robust demand across diverse industries. The market is expected to grow at a CAGR of 13.2% from 2025 to 2033, with the total market value forecasted to reach USD 4.22 billion by 2033. This remarkable growth is primarily driven by the surging adoption of location-based services, the proliferation of IoT devices, and the increasing need for real-time geospatial analytics. As per our latest research, the Geocoding API market is witnessing transformative shifts owing to advancements in cloud computing, machine learning integration, and the expanding scope of digital transformation initiatives globally.

A primary growth factor for the Geocoding API market is the exponential rise in mobile device usage and the integration of geospatial data in everyday applications. Modern businesses, from retail to logistics, are increasingly relying on geocoding solutions to enhance operational efficiency, optimize delivery routes, and improve customer engagement through personalized location-based services. The widespread adoption of smartphones and the ubiquity of GPS-enabled devices have made geospatial data a critical asset, fueling the demand for robust and scalable Geocoding APIs. This trend is further reinforced by the growing popularity of ride-sharing, food delivery, and other on-demand services that require precise location mapping and real-time address resolution.

Another significant driver is the rapid digital transformation across industries, which necessitates the integration of advanced mapping and geospatial analytics into enterprise workflows. Organizations in sectors such as transportation, real estate, and government are leveraging Geocoding APIs to streamline asset tracking, urban planning, and emergency response systems. The ability to convert physical addresses into geographic coordinates and vice versa enables businesses to gain actionable insights, enhance resource allocation, and deliver superior customer experiences. Moreover, the proliferation of big data and IoT devices has intensified the need for real-time, accurate geospatial information, further propelling the adoption of Geocoding API solutions.

The evolution of cloud computing and advancements in artificial intelligence are also catalyzing the growth of the Geocoding API market. Cloud-based deployment models offer unparalleled scalability, cost-effectiveness, and ease of integration, making them the preferred choice for enterprises of all sizes. Additionally, the integration of AI and machine learning algorithms into geocoding platforms has significantly improved the accuracy, speed, and contextual relevance of geospatial data processing. These technological advancements are enabling organizations to unlock new use cases, such as predictive analytics, geofencing, and automated asset management, thereby expanding the addressable market for Geocoding APIs.

In the context of these technological advancements, the role of Location Verification API has become increasingly significant. This API facilitates the accurate verification of physical addresses, ensuring that businesses and services can reliably reach their intended destinations. By integrating Location Verification API into their operations, companies can enhance the precision of their geocoding processes, reducing errors and improving customer satisfaction. This is particularly crucial for industries such as logistics and delivery services, where the timely and accurate delivery of goods is paramount. The API not only supports the validation of addresses but also assists in maintaining up-to-date location databases, which is essential for real-time geospatial analytics and decision-making.

From a regional perspective, North America continues to dominate the Geocoding API market, accounting for a substantial share of global revenues in 2024. The region's leadership is underpinned by the presence of major technology vendors, high digital adoption rates, and a mature ecosystem for location-based services. Europe and Asia Pacific are also witnessing robust growth, fueled by increasing investments in smart city initiatives, expanding e-commerce sectors, and government-led digitalization programs. The Asia Pacific region, in particular, is poised for the faste

Service used to geocode addresses to Sherburne County roadsas well as create new addresses locateable to the road centerline file.

The growing popularity of location-based services has resulted in the enhancement of resources for producing geographical data and the development of the amount of data kept in geographic databases. The big data stored in databases is valuable for advanced geospatial analysis in several fields, including emergency responses, crime and traffic management, disease surveillance, and more. Geocoding, a crucial preprocessing step in geospatial data analysis, involves retrieving textual descriptions of locations into geographic identifiers. Nevertheless, geocoding outcomes delivered by worldwide service providers neglect various constraints related to textual data, including misspellings, abbreviations, and non-standard names. To overcome this issue, we propose a new approach for enhancing the quality of online geocoding services through the utilization of feature selection techniques. The proposed method is based on text similarity algorithms that are utilized to match the retrieved addresses. Compared to conventional geocoding outcomes, there is potential for an improvement of approximately 10% to 25% in the address-matching procedures employed in online geocoding services. The improvement was accomplished through the utilization of two feature selection methods, specifically mutual information feature selection and minimum redundancy maximum relevance, out of a total of fourteen approaches. Furthermore, the findings indicate that it is appropriate to prioritize character-based text similarity algorithms when comparing addresses retrieved from online geocoding services.

Updated Continually

This set of addresses were geocoded for the Manager of Revenue Accounting for a webmap to be delivered on 08/14/2020The original file was geocoded against the Dallas City Geocoder: https://gis.dallascityhall.com/wwwgis/rest/services/ToolServices/DallasStreetsLocator/GeocodeServer

Web feature service for geocoding addresses and geonames in Germany for internal application in federal authorities. The service is based on the dataset of the Georeferenced Address Data — Bund (GA).